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INTR_EVENT(9) FreeBSD Kernel Developer's Manual INTR_EVENT(9)
NAME intr_event_add_handler, intr_event_create, intr_event_destroy, intr_event_handle, intr_event_remove_handler, intr_priority - kernel interrupt handler and thread API
SYNOPSIS #include <sys/param.h> #include <sys/bus.h> #include <sys/interrupt.h>
int intr_event_add_handler(struct intr_event *ie, const char *name, driver_filter_t filter, driver_intr_t handler, void *arg, u_char pri, enum intr_type flags, void **cookiep);
int intr_event_create(struct intr_event **event, void *source, int flags, int irq, void (*pre_ithread)(void *), void (*post_ithread)(void *), void (*post_filter)(void *), int (*assign_cpu)(void *, int), const char *fmt, ...);
int intr_event_destroy(struct intr_event *ie);
int intr_event_handle(struct intr_event *ie, struct trapframe *frame);
int intr_event_remove_handler(void *cookie);
u_char intr_priority(enum intr_type flags);
DESCRIPTION The interrupt event API provides methods to manage the registration and execution of interrupt handlers and their associated thread contexts.
Each interrupt event in the system corresponds to a single hardware or software interrupt source. Each interrupt event maintains a list of interrupt handlers, sorted by priority, which will be invoked when handling the event. An interrupt event will typically, but not always, have an associated kthread(9), known as the interrupt thread. Finally, each event contains optional callback functions which will be invoked before and after the handler functions themselves.
An interrupt handler contains two distinct handler functions: the filter and the thread handler. The filter function is run from interrupt context and is intended to perform quick handling such as acknowledging or masking a hardware interrupt, and queueing work for the ensuing thread handler. Both functions are optional; each interrupt handler may choose to register a filter, a thread handler, or both. Each interrupt handler also consists of a name, a set of flags, and an opaque argument which will be passed to both the filter and handler functions.
Handler Constraints The filter function is executed inside a critical(9) section. Therefore, filters may not yield the CPU for any reason, and may only use spin locks locking(9). Any memory or zone allocations in an interrupt thread must specify the M_NOWAIT flag, and any allocation errors must be handled.
The exception to these constraints is software interrupt threads, which are allowed to sleep but should be allocated and scheduled using the swi(9) interface.
Function Descriptions The intr_event_create() function creates a new interrupt event. The event argument points to a struct intr_event pointer that will reference the newly created event upon success. The source argument is an opaque pointer which will be passed to the pre_ithread, post_ithread, and post_filter callbacks. The flags argument is a mask of properties of this thread. The only valid flag currently for intr_event_create() is IE_SOFT to specify that this interrupt thread is a software interrupt. The enable and disable arguments specify optional functions used to enable and disable this interrupt thread's interrupt source. The irq argument is the unique interrupt vector number corresponding to the event. The pre_ithread, post_ithread, and post_filter arguments are callback functions that are invoked at different points while handling an interrupt. This is described in more detail in the Handler Callbacks section, below. They may be NULL to specify no callback. The assign_cpu argument points to a callback function that will be invoked when binding an interrupt to a particular CPU. It may be NULL if binding is unsupported. The remaining arguments form a printf(9) argument list that is used to build the base name of the new interrupt thread. The full name of an interrupt thread is formed by concatenating the base name of the interrupt thread with the names of all of its interrupt handlers.
The intr_event_destroy() function destroys a previously created interrupt event by releasing its resources. An interrupt event can only be destroyed if it has no handlers remaining.
The intr_event_add_handler() function adds a new handler to an existing interrupt event specified by ie. The name argument specifies a name for this handler. The filter argument provide the filter function to execute. The handler argument provides the handler function to be executed from the event's interrupt thread. The arg argument will be passed to the filter and handler functions when they are invoked. The pri argument specifies the priority of this handler, corresponding to the values defined in <sys/priority.h>. It determines the order this handler is called relative to the other handlers for this event, as well as the scheduling priority of of the backing kernel thread. flags argument can be used to specify properties of this handler as defined in <sys/bus.h>. If cookiep is not NULL, then it will be assigned a cookie that can be used later to remove this handler.
The intr_event_handle() function is the main entry point into the interrupt handling code. It must be called from an interrupt context. The function will execute all filter handlers associated with the interrupt event ie, and schedule the associated interrupt thread to run, if applicable. The frame argument is used to pass a pointer to the struct trapframe containing the machine state at the time of the interrupt. The main body of this function runs within a critical(9) section.
The intr_event_remove_handler() function removes an interrupt handler from the interrupt event specified by ie. The cookie argument, obtained from intr_event_add_handler(), identifies the handler to remove. that this handler cannot share an interrupt thread with another handler. The INTR_MPSAFE flag specifies that this handler is MP safe in that it does not need the Giant mutex to be held while it is executed. The INTR_ENTROPY flag specifies that the interrupt source this handler is tied to is a good source of entropy, and thus that entropy should be gathered when an interrupt from the handler's source triggers. Presently, the INTR_ENTROPY flag is not valid for software interrupt handlers.
Handler Callbacks Each struct intr_event is assigned three optional callback functions when it is created: pre_ithread, post_ithread, and post_filter. These callbacks are intended to be defined by the interrupt controller driver, to allow for actions such as masking and unmasking hardware interrupt signals.
When an interrupt is triggered, all filters are run to determine if any threaded interrupt handlers should be scheduled for execution by the associated interrupt thread. If no threaded handlers are scheduled, the post_filter callback is invoked which should acknowledge the interrupt and permit it to trigger in the future. If any threaded handlers are scheduled, the pre_ithread callback is invoked instead. This handler should acknowledge the interrupt, but it should also ensure that the interrupt will not fire continuously until after the threaded handlers have executed. Typically this callback masks level-triggered interrupts in an interrupt controller while leaving edge-triggered interrupts alone. Once all threaded handlers have executed, the post_ithread callback is invoked from the interrupt thread to enable future interrupts. Typically this callback unmasks level-triggered interrupts in an interrupt controller.
RETURN VALUES The intr_event_add_handler(), intr_event_create(), intr_event_destroy(), intr_event_handle(), and intr_event_remove_handler() functions return zero on success and non-zero on failure. The intr_priority() function returns a process priority corresponding to the passed in interrupt flags.
EXAMPLES The swi_add(9) function demonstrates the use of intr_event_create() and intr_event_add_handler().
int swi_add(struct intr_event **eventp, const char *name, driver_intr_t handler, void *arg, int pri, enum intr_type flags, void **cookiep) { struct intr_event *ie; int error = 0;
if (flags & INTR_ENTROPY) return (EINVAL);
ie = (eventp != NULL) ? *eventp : NULL;
if (ie != NULL) { if (!(ie->ie_flags & IE_SOFT)) return (EINVAL); } else { error = intr_event_create(&ie, NULL, IE_SOFT, 0, error = intr_event_add_handler(ie, name, NULL, handler, arg, PI_SWI(pri), flags, cookiep); } return (error); }
ERRORS The intr_event_add_handler() function will fail if:
[EINVAL] The ie or name arguments are NULL.
[EINVAL] The handler and filter arguments are both NULL.
[EINVAL] The IH_EXCLUSIVE flag is specified and the interrupt thread ie already has at least one handler, or the interrupt thread ie already has an exclusive handler.
The intr_event_create() function will fail if:
[EINVAL] A flag other than IE_SOFT was specified in the flags parameter.
The intr_event_destroy() function will fail if:
[EINVAL] The ie argument is NULL.
[EBUSY] The interrupt event pointed to by ie has at least one handler which has not been removed with intr_event_remove_handler().
The intr_event_handle() function will fail if:
[EINVAL] The ie argument is NULL.
[EINVAL] There are no interrupt handlers assigned to ie.
[EINVAL] The interrupt was not acknowledged by any filter and has no associated thread handler.
The intr_event_remove_handler() function will fail if:
[EINVAL] The cookie argument is NULL.
SEE ALSO critical(9), kthread(9), locking(9), malloc(9), swi(9), uma(9)
HISTORY Interrupt threads and their corresponding API first appeared in FreeBSD 5.0.
FreeBSD 14.0-RELEASE-p11 October 30, 2022 FreeBSD 14.0-RELEASE-p11